Electronic Tricks Lora/LoraWan shield for Raspberry Pi Zero and PI3

For the example code so far I had been using the Dragino LoRa GPS HAT for Raspberry PI which, after looking at the schematic (to figure out how the chip select line was connected) worked pretty well.

I had also purchased a Lora/LoRaWAN shield for Raspberry PI Zero and PI3 from Tindie (plus some unpopulated printed circuit boards so I can try building a RFM69HCW based shield).

The board didn’t fit on my Raspberry PI 2 & 3 devices so I used a Dexter industries Grove PI0 Shield as a temporary spacer to lift the antenna connector above the USB sockets.

The RFM95 chip select line is connected to pin 24 (GPIO8), the reset line to pin 29(GPIO5) and the interrupt line (RFM95 DIO0) to pin 22(GPIO25).


My board doesn’t have any Light Emitting Diodes (LEDs) so it was straight into reading register values

// Copyright (c) July 2018, devMobile Software
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//     http://www.apache.org/licenses/LICENSE-2.0
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// See the License for the specific language governing permissions and
// limitations under the License.
namespace devMobile.IoT.Rfm9x.ElectronicTricksSPI
	using System;
	using System.Diagnostics;
	using System.Threading;
	using Windows.ApplicationModel.Background;
	using Windows.Devices.Spi;

	public sealed class StartupTask : IBackgroundTask
		public void Run(IBackgroundTaskInstance taskInstance)
			SpiController spiController = SpiController.GetDefaultAsync().AsTask().GetAwaiter().GetResult();
			var settings = new SpiConnectionSettings(0) // GPIO8 Electronic Tricks
				ClockFrequency = 500000,
				Mode = SpiMode.Mode0,   // From SemTech docs pg 80 CPOL=0, CPHA=0

			SpiDevice Device = spiController.GetDevice(settings);

			while (true)
				byte[] writeBuffer = new byte[] { 0x42 }; // RegVersion
				byte[] readBuffer = new byte[1];

				Device.TransferSequential(writeBuffer, readBuffer);

				byte registerValue = readBuffer[0];
				Debug.WriteLine("Register 0x{0:x2} - Value 0X{1:x2} - Bits {2}", 0x42, registerValue, Convert.ToString(registerValue, 2).PadLeft(8, '0'));


The debug output confirmed I was reading the right value from the RegVer register

Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010
Register 0x42 - Value 0X12 - Bits 00010010

The antenna connector not clearing the USB socket is an issue which I’ll solve with a socket like the one on the GrovePI which has longer leads and acts as a spacer.

Azure Meetup-Budget tank of 91 IoT

The premise of my Azure Meetup presentation was could you build an interesting project on a rainy weekend afternoon with a constrained budget (tank of 91 octane petrol) and minimal soldering .


Our family car is a VW Passat V6 4Motion which has a 62 Litre tank. The driver usually doesn’t usually stop to fill up until the fuel light has been on for a bit which helped.


Based on the most recent receipt the budget was NZD132.

Where possible I purchased parts locally (the tech equivalent of food miles) or on special.

My bill of materials (prices as at 2018-06) was on budget.

The devDuino V2.2 and nRF24L01 module were USD26.20 approx. NZD37.50 (including freight) from elecrow.


I powered my Raspberry PI with a spare cellphone charger (make sure it can supply enough current to reliably power the device).

The devDuino V2.has an ATSHA204A which provides a guaranteed unique 72-bit serial number (makes it harder to screw up provisioning devices in the field).

I use a 32G MicroSD rather than a 16G MicroSD card as I have had issued with 16G cards getting corrupted by more recent upgrades (possibly running out of space?)

The Raspberry PI shield requires a simple modification to enable interrupt driven operation.

My sample devDuino V2.2 client uses an external temperature and humidity sensor, modifying this code to use the onboard temperature sensor an MCP9700 will be covered in another post.

The devDuino V2 is a little bit cheaper USD15.99 NZD37.31, has the same onboard temperature sensor as the V2.2 but no unique serial number chip.

The devDuino V4.0 has an onboard HTU21D temperature + humidity sensor but no unique serial number and the batteries are expensive.

The code and deployment instructions for the nRF24L01 field gateway applications for AdaFruit.IO and Azure IoT Hub/Azure IoT Central are available on hackster.IO.


AdaFruit.IO has free and USD10.00/month options which work well for many hobbyist projects.


nRF24 Windows 10 IoT Core Hardware

Taking my own advice I decided to purchase a couple of Raspberry Pi to NRF24L01 shields from Ceech a vendor on Tindie.

The nRF24L01 libraries for my .Net Micro framework and WIndows 10 IoT Core devices use an interrupt driver approach rather than polling status registers to see what is going on.

Like most Raspberry PI shields intended to be used with a *nix based operating system the interrupt pin was not connected to a General Purpose Input/Output (GPIO) pin.


My first step was to add a jumper wire from the pin 8 on the nRF24L01 to GPIO pin 17 on Raspberry PI connector.

I then downloaded the techfooninja Radios.RF24 library for Windows IoT core and update the configuration to suit my modifcations. In the TestApp the modifications were limited to changing the interrupt pin from GPI 4 to GPO 17

private const byte IRQ_PIN = 4;

private const byte IRQ_PIN = 17;

I used a socket for the nRF24L01 device so I can trial different devices, for a production system I would solder the device to the shield to improve reliability.


I then ran the my test application software in a stress test rig overnight to check for any reliability issues. The 5 x netduino devices were sending messages every 500mSec


nRF24L01 Raspberry PI Gateway Hardware

For those who came to my MS Ignite AU Intelligent Cloud booth session

Building Wireless Field Gateways

Connecting wireless sensor nodes to the cloud is not the mission it used to be, because the Azure team (and many OS projects) have developed tooling which can help hobbyist and professional developers build solutions. How could you build a home scale robust, reliable and secure solution with off the shelf kit without blowing the budget?

Sparkfun nRF24L01 module &Adafruit perma proto hat

NRF24L01 Raspberry PI DIY Gateway Hardware

BoM (all prices as at Feb 2016)

You will also need some short lengths of wire and a soldering iron.

For those who want an “off the shelf” solution (still requires a minor modification for interrupt support) I have used the Raspberry Pi to NRF24l01+ Shield USD9.90


Instructions for modifications and software to follow.